### TBA by Morgan Weiler

- Series
- Geometry Topology Seminar
- Time
- Monday, September 21, 2020 - 14:00 for 1 hour (actually 50 minutes)
- Location
- Skile 006
- Speaker
- Morgan Weiler – Rice

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- Series
- Geometry Topology Seminar
- Time
- Monday, September 21, 2020 - 14:00 for 1 hour (actually 50 minutes)
- Location
- Skile 006
- Speaker
- Morgan Weiler – Rice

- Series
- Applied and Computational Mathematics Seminar
- Time
- Monday, August 24, 2020 - 13:55 for 1 hour (actually 50 minutes)
- Location
- Bluejeans (online)
- Speaker
- Prof. Changyou Chen – University at Buffalo

- Series
- Geometry Topology Seminar
- Time
- Monday, August 17, 2020 - 14:00 for 1 hour (actually 50 minutes)
- Location
- https://bluejeans.com/373562881
- Speaker
- Tye Lidman – NCSU

The three-dimensional Poincare conjecture shows that any closed three-manifold other than the three-sphere has non-trivial fundamental group. A natural question is how to measure the non-triviality of such a group, and conjecturally this can be concretely realized by a non-trivial representation to SU(2). We will show that the fundamental groups of three-manifolds with incompressible tori admit non-trivial SU(2) representations. This is joint work with Juanita Pinzon-Caicedo and Raphael Zentner.

The speaker will hold online office hours from 3:15-4:15 pm for interested graduate students and postdocs.

- Series
- CDSNS Colloquium
- Time
- Wednesday, July 22, 2020 - 09:00 for 1 hour (actually 50 minutes)
- Location
- Bluejeans: https://primetime.bluejeans.com/a2m/live-event/xsgxxwbh
- Speaker
- Lewis Bowen – UT Austin – lpbowen@math.utexas.edu

In 1960, Furstenberg and Kesten introduced the problem of describing the asymptotic behavior of products of random matrices as the number of factors tends to infinity. Oseledets’ proved that such products, after normalization, converge almost surely. This theorem has wide-ranging applications to smooth ergodic theory and rigidity theory. It has been generalized to products of random operators on Banach spaces by Ruelle and others. I will explain a new infinite-dimensional generalization based on von Neumann algebra theory which accommodates continuous Lyapunov distribution. No knowledge of von Neumann algebras will be assumed. This is joint work with Ben Hayes (U. Virginia) and Yuqing Frank Lin (UT Austin, Ben-Gurion U.).

- Series
- Dynamical Systems Working Seminar
- Time
- Tuesday, July 21, 2020 - 12:00 for 1 hour (actually 50 minutes)
- Location
- Bluejeans: https://primetime.bluejeans.com/a2m/live-event/fsvsfsua
- Speaker
- Yuqing Lin – UT Austin – ylin@math.utexas.edu

**Please Note:** This is an expository talk, to be paired with the CDSNS Colloquium held the next day.

This is a gentle introduction to the classical Oseledets' Multiplicative Ergodic Theorem (MET), which can be viewed as either a dynamical version of the Jordan normal form of a matrix, or a matrix version of the pointwise ergodic theorem (which itself can be viewed as a generalization of the strong law of large numbers). We will also sketch Raghunathan's proof of the MET and discuss how the MET can be applied to smooth ergodic theory.

- Series
- CDSNS Colloquium
- Time
- Wednesday, July 8, 2020 - 12:00 for 1 hour (actually 50 minutes)
- Location
- Bluejeans: https://primetime.bluejeans.com/a2m/live-event/xsgxxwbh
- Speaker
- Bhanu Kumar – Georgia Tech – bkumar30@gatech.edu

When the planar circular restricted 3-body problem (RTBP) is periodically perturbed, most unstable resonant periodic orbits become invariant tori. In this study, we 1) develop a quasi-Newton method which simultaneously solves for the tori and their center, stable, and unstable directions; 2) implement continuation by both perturbation parameter as well as rotation numbers; 3) compute Fourier-Taylor parameterizations of the stable and unstable manifolds; 4) globalize these manifolds; and 5) compute homoclinic and heteroclinic connections. Our methodology improves on efficiency and accuracy compared to prior studies, and applies to a variety of periodic perturbations. We demonstrate the tools on the planar elliptic RTBP. This is based on joint work with R. Anderson and R. de la Llave.

- Series
- CDSNS Colloquium
- Time
- Wednesday, July 1, 2020 - 09:00 for 1.5 hours (actually 80 minutes)
- Location
- Bluejeans: https://primetime.bluejeans.com/a2m/live-event/xsgxxwbh
- Speaker
- Matteo Tanzi – New York University – mt3986@nyu.edu

We investigate dynamical systems obtained by coupling an Anosov diffeomorphism and a N-pole-to-S-pole map of the circle. Both maps are uniformly hyperbolic; however, they have contrasting character, as the first one is chaotic while the second one has “orderly" dynamics. The first thing we show is that even weak coupling can produce interesting phenomena: when the attractor of the uncoupled system is not normally hyperbolic, most small interactions transform it from a smooth surface to a fractal-like set. We then consider stronger couplings in which the action of the Anosov diffeomorphism on the circle map has certain monotonicity properties. These couplings produce genuine obstructions to uniform hyperbolicity; however, the monotonicity conditions make the system amenable to study by leveraging techniques from the geometric and ergodic theories of hyperbolic systems. In particular, we can show existence of invariant cones and SRB measures.

This is joint work with Lai-Sang Young.

- Series
- Applied and Computational Mathematics Seminar
- Time
- Monday, June 22, 2020 - 13:55 for 1 hour (actually 50 minutes)
- Location
- https://bluejeans.com/963540401
- Speaker
- Dr. Yuan Gao – Duke University – yg86@duke.edu

**Please Note:** virtual (online) seminar

We work on Langevin dynamics with collected dataset that distributed on a manifold M in a high dimensional Euclidean space.
Through the diffusion map, we learn the reaction coordinates for N which is a manifold isometrically embedded into a low dimensional Euclidean space. This enables us to efficiently approximate the dynamics described by a Fokker-Planck equation on the manifold N. Based on this, we propose an implementable, unconditionally stable, data-driven upwind scheme which automatically incorporates the manifold structure of N and enjoys the weighted l^2 convergence to the Fokker-Planck equation. The proposed upwind scheme leads to a Markov chain with transition probability between the nearest neighbor points, which enables us to directly conduct manifold-related computations such as finding the optimal coarse-grained network and the minimal energy path that represents chemical reactions or conformational changes.
To acquire information about the equilibrium potential on manifold N, we apply a Gaussian Process regression algorithm to generate equilibrium potentials for a new physical system with new parameters. Combining with the proposed upwind scheme, we can calculate the trajectory of the Fokker-Planck equation on N based on the generated equilibrium potential. Finally, we develop an algorithm to pullback the trajectory to the original high dimensional space as a generative data for the new physical system. This is a joint work with Nan Wu and Jian-Guo Liu.

- Series
- CDSNS Colloquium
- Time
- Wednesday, June 17, 2020 - 09:00 for 1.5 hours (actually 80 minutes)
- Location
- Bluejeans: https://primetime.bluejeans.com/a2m/live-event/xsgxxwbh
- Speaker
- Caroline Wormell – University of Sydney – caroline.wormell@sydney.edu.au

Full-branch uniformly expanding maps and their long-time statistical quantities are commonly used as simple models in the study of chaotic dynamics, as well as being of their own mathematical interest. A wide range of algorithms for computing these quantities exist, but they are typically unspecialised to the high-order differentiability of many maps of interest, and so have a weak tradeoff between computational effort and accuracy.

This talk will cover a rigorous method to calculate statistics of these maps by discretising transfer operators in a Chebyshev polynomial basis. This discretisation is highly efficient: I will show that, for analytic maps, numerical estimates obtained using this discretisation converge exponentially quickly in the order of the discretisation, for a polynomially growing computational cost. In particular, it is possible to produce (non-validated) estimates of most statistical properties accurate to 14 decimal places in a fraction of a second on a personal computer. Applications of the method to the study of intermittent dynamics and the chaotic hypothesis will be presented.

- Series
- CDSNS Colloquium
- Time
- Wednesday, June 3, 2020 - 09:00 for 1.5 hours (actually 80 minutes)
- Location
- Bluejeans: https://primetime.bluejeans.com/a2m/live-event/xsgxxwbh
- Speaker
- Jason Mireles-James – Florida Atlantic University – jmirelesjames@fau.edu

Delay differential equations (DDEs) are important in physical applications where there is a time lag in communication between subsystems. From a mathematical point of view DDEs are an interesting source of problems as they provide natural examples of infinite dimensional dynamical systems. I'll discuss some spectral numerical methods for computing invariant manifolds for DDEs and present some applications.

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